Comparative Effects of Ions, Molecular Crowding, and Bulk DNA on

Aug 29, 2016 - The enzyme is an emerging target for antimicrobial therapy. The small molecule inhibitor A110 has been ... Abstract | Full Text HTML | ...
0 downloads 0 Views 2MB Size
Article pubs.acs.org/biochemistry

Comparative Effects of Ions, Molecular Crowding, and Bulk DNA on the Damage Search Mechanisms of hOGG1 and hUNG Shannen L. Cravens and James T. Stivers* Department of Pharmacology and Molecular Sciences, The Johns Hopkins University School of Medicine, 725 North Wolfe Street, Baltimore, Maryland 21205-2185, United States S Supporting Information *

ABSTRACT: The energetic nature of the interactions of DNA base excision repair glycosylases with undamaged and damaged DNA and the nuclear environment are expected to significantly impact the time it takes for these enzymes to search for damaged DNA bases. In particular, the high concentration of monovalent ions, macromolecule crowding, and densely packed DNA chains in the cell nucleus could alter the search mechanisms of these enzymes as compared to findings in dilute buffers typically used in in vitro experiments. Here we utilize an in vitro system where the concerted effects of monovalent ions, macromolecular crowding, and high concentrations of bulk DNA chains on the activity of two paradigm human DNA glycosylases can be determined. We find that the energetic nature of the observed binding free energies of human 8-oxoguanine DNA glycosylase (hOGG1) and human uracil DNA glycosylase (hUNG) for undamaged DNA are derived from different sources. Although hOGG1 uses primarily nonelectrostatic binding interactions with nonspecific DNA, hUNG uses a salt-dependent electrostatic binding mode. Both enzymes turn to a nonelectrostatic mode in their specific complexes with damaged bases in DNA, which enhances damage site specificity at physiological ion concentrations. Neither enzyme was capable of efficiently locating and removing their respective damaged bases in the combined presence of physiological ions and a bulk DNA chain density approximating that found in the nucleus. However, the addition of an inert crowding agent to mimic macromolecular crowding in the nucleus largely restored their ability to track DNA chains and locate damaged sites. These findings suggest how the concerted action of monovalent ions and crowding could contribute to efficient DNA damage recognition in cells.

D

glycosylases with undamaged and damaged DNA and the contribution of the nuclear environment to the search time and recognition mechanism. Indeed, the effects of crowding in a human cell are significant with macromolecule concentrations of ∼100−300 mg/ml, indicating that 10−40% of the total cellular volume is consumed by large molecules (often called the excluded volume).10,13,17 We have undertaken a detailed analysis of the effects of key solution parameters (i.e., ion concentration and crowding agents) on the specificity of human uracil DNA glycosylase (hUNG) for undamaged and uracil containing DNA.8,9 This work has shown that the positively charged DNA binding site of hUNG promotes weak electrostatic interactions with undamaged DNA chains. These weak interactions facilitate two general types of translocation events along DNA chains: associative translocations where the enzyme remains within the DNA ion cloud and moves relatively short 5 nM were only used in experiments containing salDNA for the same reasons outlined above for hUNG. Aliquots of the reaction were quenched with 20 μL formamide loading buffer and heated for 15 min at 95 °C. For both enzymes, the discrete DNA fragments generated by heating were resolved by electrophoresis on a denaturing 10% PAGE gel containing 7 M urea. All gels were dried, exposed overnight to a storage phosphor screen and imaged with a Typhoon 8600 phosphorimager (GE Healthcare). All gel images were quantified using QuantityOne (Bio-Rad) by the box method and background corrected as described above. The observed transfer probabilities (Ptransobs) were determined using eq 5, and the time-independent transfer probability (Ptrans) was calculated by linear extrapolation of the Ptransobs values to zero time as previously described.34,36 Ptrans obs =

[A] + [C] − [AB] − [BC] [A] + [C] + [AB] + [BC]

The fractional extent of reaction at each time was quantified by phosphorimaging of the gels, and the reaction rates for both hUNG and hOGG1 under all tested conditions were determined from the linear slopes of plots of product concentration against time using Prism. Turnover Rate Determination. The steady-state turnover rates of hUNG and hOGG1 under various solution conditions were determined using the S20U and S20oxoG substrates, respectively. The fraction reaction at each time point was calculated from the ratio of the summed intensities of all product bands to the summed intensity of substrate and product bands. The fraction reaction was plotted as a function of time, and the slopes were determined by linear regression fitting using data where the reaction had proceeded to